1. Chapter 37: Plant Nutrition
1. What are the nutritional requirements of plants?

2. Figure 37.2 The uptake of nutrients by a plant: a review
CO2, the source
of carbon for
Photosynthesis,
diffuses into
leaves from the
air through
stomata.
Through
stomata, leaves
expel H2O and
O2.
H2O O2
CO2
Roots take in
O2 and expel
CO2. The plant
uses O2 for cellular
respiration but is a net O2 producer.
Roots absorb
H2O and
minerals from
the soil.
Minerals

3. Chapter 37: Plant Nutrition
What are the nutritional requirements of plants?
Why do plants need K+?
Macronutrients – needed in large amounts (9)
Micronutrients – needed in small amounts (8)
Mg++ P S N

4. Table 37.1 Essential Elements in Plants

5. Chapter 37: Plant Nutrition
What are the nutritional requirements of plants?
Why do plants need K+?
What makes up soil?
Weathered rock
Topsoil – mixture of weathered rock, living organisms, & humus
Humus – remains of partially decayed organic matter
Loams – most fertile soils made of equal amounts of clay, silt & sand
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6. Figure 37.5 Soil horizons The A horizon is the topsoil, a mixture of
broken-down rock of various textures, living
organisms, and decaying organic matter.
The B horizon contains much less organic
matter than the A horizon and is less
weathered.
The C horizon, composed mainly of partially
broken-down rock, serves as the “parent”
material for the upper layers of soil. A B C

7. Chapter 37: Plant Nutrition
What are the nutritional requirements of plants?
Why do plants need K+?
What makes up soil?
How do minerals become available to plant roots?
- Cation exchange
Mg++ P S N

8. Figure 37.6 The availability of soil water and minerals
Soil particle surrounded by
film of water
Root hair
Water available to plant
Air space
H2O + CO2
H2CO3
HCO3– +
Soil particle K+
Cu2+
Ca2+
Mg2+ H+ –
(a) Soil water. A plant cannot extract all the water in the soil because some of it is tightly held by hydrophilic soil particles. Water bound less tightly to soil particles can be absorbed by the root.
(b) Cation exchange in soil. Hydrogen ions (H+) help make nutrients available by displacing positively charged minerals (cations such as Ca2+) that were bound tightly to the surface of negatively charged soil particles. Plants contribute H+ by secreting it from root hairs and also by cellular respiration, which releases CO2 into the soil solution, where it reacts with H2O to form carbonic acid (H2CO3). Dissociation of this acid adds H+ to the soil solution.

9. Chapter 37: Plant Nutrition
What are the nutritional requirements of plants?
Why do plants need K+?
What makes up soil?
How do minerals become available to plant roots?
How is soil conservation achieved?
Fertilizers
N-P-K
Organic
Irrigation - problems
Erosion prevention
Mg++ P S N

10. Chapter 37: Plant Nutrition
What are the nutritional requirements of plants?
Why do plants need K+?
What makes up soil?
How do minerals become available to plant roots?
How is soil conservation achieved?
How do plants obtain nitrogen?
nitrogen-fixing bacteria
Mg++ P S N

11. Nitrogen-fixing bacteria
Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants
Atmosphere N2
Soil
Nitrogen-fixing bacteria
Organic material (humus)
NH3 (ammonia)
NH4 + (ammonium)
H+ (from soil)
Ammonifying bacteria

12. Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants
Atmosphere N2
Soil
Nitrogen-fixing bacteria
Organic material (humus)
NH3 (ammonia)
NH4 + (ammonium)
H+ (from soil)
NO3 – (nitrate)
Nitrifying bacteria
Denitrifying bacteria
Ammonifying bacteria

13. Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants
Atmosphere N2
Soil
Nitrogen-fixing bacteria
Organic material (humus)
NH3 (ammonia)
NH4 + (ammonium)
H+ (from soil)
NO3 – (nitrate)
Nitrifying bacteria
Denitrifying bacteria
Root
NH4 +
Nitrate and nitrogenous organic compounds exported in xylem to shoot system
Ammonifying bacteria
Assimilation
Legumes have root nodules with symbiotic bacteria
Rhizobium

14. Figure 37.10 Root nodules on legumes
(a) Pea plant root. The bumps on this pea plant root are nodules containing Rhizobium bacteria. The bacteria fix nitrogen and obtain photosynthetic products supplied by the plant.
(b) Bacteroids in a soybean root nodule. In this TEM, a cell from a root nodule of soybean is filled with bacteroids in vesicles. The cells on the left are uninfected.
5 m
Bacteroids
within
vesicle
Nodules
Roots

15. Chapter 37: Plant Nutrition
What are the nutritional requirements of plants?
Why do plants need K+?
What makes up soil?
How do minerals become available to plant roots?
How is soil conservation achieved?
How do plants obtain nitrogen?
What are some nutritional adaptations that aid plants?
Mg++ P S N

16. Figure 37.13 Unusual Nutritional Adaptations in Plants
Staghorn fern, an epiphyte
EPIPHYTES
PARASITIC PLANTS
CARNIVOROUS PLANTS
Mistletoe, a photosynthetic parasite
Dodder, a nonphotosynthetic parasite
Host’s phloem
Haustoria
Indian pipe, a nonphotosynthetic parasite
Venus’ flytrap
Pitcher plants
Sundews
Dodder

17. 37.13 Sun Dew Trap Prey